Low profile electrodes for a shock wave catheter

ABSTRACT

The invention provides a device for generating shock waves. The device may comprise an elongated tube and a conductive sheath circumferentially mounted around the elongated tube. The device may further comprise first and second insulated wires extending along the outer surface of the elongated tube. A portion of the first insulated wire is removed to form a first inner electrode, which is adjacent to a first side edge of the conductive sheath. A portion of the second insulated wire is removed to form a second inner electrode, which is adjacent to a second side edge of the conductive sheath. Responsive to a high voltage being applied across the first inner electrode and the second inner electrode, a first shock wave is created across the first side edge and the first inner electrode, and a second shock wave is created across the second side edge and the second inner electrode.

PRIORITY

This application is a continuation of U.S. Pat. Application Serial No. 16/893,400, filed Jun. 4, 2020, which is a continuation of U.S. Pat. Application Serial No. 15/817,073, filed Nov. 17, 2017, now U.S. Patent No. 10,709,462, issued Jul. 14, 2020, the entire disclosure of each of which is incorporated herein by reference.

FIELD

The present disclosure relates generally to shock wave electrodes, and more specifically, to electrodes for the generation of shock waves within vascular structures.

BACKGROUND

The present invention relates to a treatment system for percutaneous coronary angioplasty or peripheral angioplasty in which an angioplasty balloon is used to dilate a lesion (e.g., calcified lesion) and restore normal blood flow in the artery. In this type of procedure, a catheter carrying a balloon is advanced into the vasculature along a guide wire until the balloon is aligned with calcified plaques. The balloon is then pressurized to reduce or break the calcified plaques and push them back into the vessel wall.

More recently, the assignee herein has developed a treatment system that includes electrodes within an angioplasty type balloon. In use, the balloon is advanced to the region of an occlusion. The balloon is then partially pressurized with a conductive fluid. A series of high voltage pulses are applied to the electrodes within the balloon, with each pulse generating a shock wave in the conductive fluid. The shock waves pass through the balloon wall and into the occlusion, cracking the calcified plaques. Once the calcified plaques are cracked, the balloon can be further expanded to open the vessel. Such system is disclosed in U.S. Patent No. 8,956,371 and U.S. Patent No. 8,888,788, both of which are incorporated herein by reference. Further, the assignee herein has developed techniques for providing an electrode on the tip of a guide wire for generating forward directed shock waves. This approach is disclosed in U.S. Patent Publication No. 2015/0320432, also incorporated herein by reference.

The present invention relates to yet another alternative for placing shock wave electrodes near an occlusion. This approach can be used along or in conjunction with an angioplasty balloon.

BRIEF SUMMARY

The invention provides a device for generating shock waves. In some embodiments, the device comprises an elongated tube and a conductive sheath circumferentially mounted around the elongated tube. The device further comprises a first insulated wire extending along the outer surface of the elongated tube and a second insulated wire extending along the outer surface of the elongated tube. A portion of the first insulated wire is removed to form a first inner electrode and the first inner electrode is adjacent to a first side edge of the conductive sheath. A portion of the second insulated wire is removed to form a second inner electrode and the second inner electrode is adjacent to a second side edge of the conductive sheath. When a high voltage is applied across the first inner electrode and the second inner electrode, a current is configured to flow from the first wire to the first side edge of the conductive sheath and from the second side edge of the conductive sheath to the second wire. A first shock wave is created across the first side edge of the conductive sheath and the first inner electrode, and a second shock wave is created across the second side edge of the conductive sheath and the second inner electrode.

In some embodiments, the device comprises an elongated tube and three conductive sheaths each circumferentially mounted around the elongated tube. The device further comprises a first insulated wire, a second insulated wire, a third insulated wire, and an insulated common ground wire, each extending along the outer surface of the elongated tube. A portion of the first insulated wire is removed to form a first inner electrode; two portions of the second insulated wire are removed to form a second inner electrode and a third inner electrode; two portions of the third insulated wire are removed to form a fourth inner electrode and a fifth inner electrode; a portion of the insulated common ground wire is removed to form a sixth inner electrode. When a high voltage is applied across the first wire and the insulated common ground wire, a current is configured to flow from the first wire to a first side edge of the first conductive sheath, from a second side edge of the first conductive sheath to the second wire, from the second wire to a first side edge of the second conductive sheath, from a second side edge of the second conductive sheath to the third wire, from the third wire to a first side edge of the third conductive sheath, from a second side edge of the third conductive sheath to the insulated common ground wire. Accordingly, a first shock wave is created across the first side edge of the first conductive sheath and the first inner electrode, a second shock wave is created across the second side edge of the first conductive sheath and the second inner electrode, a third shock wave is created across the first side edge of the second conductive sheath and the third inner electrode, a fourth shock wave is created across the second side edge of the second conductive sheath and the fourth inner electrode, a fifth shock wave is created across the first side edge of the third conductive sheath and the fifth inner electrode, and a sixth shock wave is created across the second side edge of the third conductive sheath and the sixth inner electrode.

In some embodiments, a device for generating shock waves comprises an elongated tube and four conductive sheaths each circumferentially mounted around the elongated tube. The device further comprises a first insulated wire, a second insulated wire, a third insulated wire, a fourth insulated wire, and an insulated common ground wire, each extending along the outer surface of the elongated tube. A portion of the first insulated wire is removed to form a first inner electrode; two portions of the second insulated wire are removed to form a second inner electrode and a third inner electrode; a portion of the third insulated wire is removed to form a fifth inner electrode; two portions of the fourth insulated wire are removed to form a sixth inner electrode and a seventh inner electrode; two portions of the insulated common ground wire are removed to form a fourth inner electrode and an eighth inner electrode. When a high voltage is applied across the first wire and the insulated common ground wire, a first current is configured to flow from the first wire to a first side edge of the first conductive sheath to generate a first shock wave across the first side edge of the first conductive sheath and the first inner electrode, from a second side edge of the first conductive sheath to the second wire to generate a second shock wave across the second side edge of the first conductive sheath and the second inner electrode, from the second wire to a first side edge of the second conductive sheath to generate a third shock wave across the first side edge of the second conductive sheath and the third inner electrode, from a second side edge of the second conductive sheath to the insulated common ground wire to generate a fourth shock wave across the second side edge of the second conductive sheath and the fourth inner electrode. When a high voltage is applied across the third wire and the insulated common ground wire, a second current is configured to flow from the third insulated wire to a first side edge of the third conductive sheath to generate a fifth shock wave across the first side edge of the third conductive sheath and the fifth inner electrode, from a second side edge of the third conductive sheath to the fourth insulated wire to generate a sixth shock wave across the second side edge of the third conductive sheath and the sixth inner electrode, from the fourth insulated wire to a first side edge of the fourth conductive sheath to generate a seventh shock wave across the first side edge of the fourth conductive sheath and the seventh inner electrode, and from a second side edge of the fourth conductive sheath to the insulated common ground wire to generate an eighth shock wave across the second side edge of the fourth conductive sheath and the eighth inner electrode.

DESCRIPTION OF THE FIGURES

FIG. 1 depicts an exemplary shock wave angioplasty device having a plurality of electrode assemblies, in accordance with some embodiments.

FIG. 2A depicts a set of shock wave electrode assemblies in an exemplary shock wave angioplasty device that may be activated to generate shock waves at 4 locations, in accordance with some embodiments.

FIG. 2B depicts the connectivity between a plurality of inner electrodes and sheaths to attain the configuration of FIG. 2A, in accordance with some embodiments.

FIG. 2C depicts an exemplary electrode assembly, in accordance with some embodiments.

FIG. 2D depicts an exemplary electrode assembly, in accordance with some embodiments.

FIG. 2E schematically depicts an electrical diagram of the configuration of FIG. 2A, in accordance with some embodiments.

FIG. 3A depicts a set of shock wave electrode assemblies in an exemplary shock wave angioplasty device that may be activated to generate shock waves at 6 locations, in accordance with some embodiments.

FIG. 3B depicts the connectivity between a plurality of inner electrodes and sheaths to attain the configuration of FIG. 3A, in accordance with some embodiments.

FIG. 4A depicts a set of shock wave electrode assemblies in an exemplary shock wave angioplasty device that may be activated to generate shock waves at 8 locations, in accordance with some embodiments.

FIG. 4B depicts the connectivity between a plurality of inner electrodes and sheaths to attain the configuration of FIG. 4A, in accordance with some embodiments.

FIG. 4C schematically depicts an electrical diagram of the configuration of FIG. 4A, in accordance with some embodiments.

FIG. 4D schematically depicts an electrical diagram of the configuration of FIG. 4A, in accordance with some embodiments.

FIG. 5 depicts a set of shock wave electrode assemblies in an exemplary shock wave angioplasty device that may be activated to generate shock waves at 10 locations, in accordance with some embodiments.

FIG. 6A depicts an exemplary sheath that may be used in an electrode assembly, in accordance with some embodiments.

FIG. 6B depicts an exemplary sheath that may be used in an electrode assembly, in accordance with some embodiments.

FIG. 6C depicts an exemplary sheath that may be used in an electrode assembly, in accordance with some embodiments.

FIG. 6D depicts an exemplary sheath that may be used in an electrode assembly, in accordance with some embodiments.

FIG. 7A depicts an exemplary construction of an electrode assembly, in accordance with some embodiments.

FIG. 7B depicts an exemplary construction of an electrode assembly, in accordance with some embodiments.

FIG. 7C depicts an exemplary construction of an electrode assembly, in accordance with some embodiments.

DETAILED DESCRIPTION

The following description is presented to enable a person of ordinary skill in the art to make and use the various embodiments. Descriptions of specific devices, techniques, and applications are provided only as examples. Various modifications to the examples described herein will be readily apparent to those of ordinary skill in the art, and the general principles defined herein may be applied to other examples and applications without departing from the spirit and scope of the various embodiments. Thus, the various embodiments are not intended to be limited to the examples described herein and shown, but are to be accorded the scope consistent with the claims.

The assignee herein has developed a number of low-profile shock wave electrodes that may be suitable for use in angioplasty and/or valvuloplasty procedures. For example, in U.S. Pat. No. 8,888,788, the assignee discloses a low-profile electrode assembly comprising an inner electrode, an insulating layer overlaying the inner electrode, and an outer electrode. The outer electrode may be a conductive sheath having a central opening that is coaxially aligned with an opening in the insulating layer. In operation, plasma arcs can be formed across the inner electrode and the opening in the outer electrode to generate shock waves. The above-described design reduces the crossing-profile of the shock wave device because the inner electrode, the outer electrode, and the insulating layer are stacked, thus allowing the shock wave device to easily navigate through, access, and treat target vascular tissues.

In operation, the plasma arcs generated across the inner electrode and the outer electrode cause erosion in the conductive sheath, resulting in widening of the opening in both directions. As the opening widens, it becomes more difficult to control the generation, location, and/or magnitude of plasma arcs (and therefore shock waves), thus negatively impacting the longevity of the electrode assembly.

Described herein are shock wave electrode assemblies that are designed to be low-profile and durable. In some embodiments, an outer electrode is formed by a conductive sheath without an opening on the outer surface, and an inner electrode is formed by removing a portion of an insulated wire (e.g., cutting a hole in the insulating layer near the end of the wire) to expose an electrically conductive portion of the insulated wire. The inner electrode is placed a controlled distance apart from the side edge of the conductive sheath to allow for a reproducible arc for a given current and voltage. In operation, plasma arcs may be formed across the inner electrode and the side edge of the conductive sheath, rather than across the inner electrode and an opening of the sheath. As such, the plasma arcs would cause erosion only in the one direction into the side edge, rather than causing erosion in both directions to widen the opening in the previous designs. Thus, the longevity of the electrode assembly is effectively doubled. Additionally, the present design eliminates the use of an insulated layer stacked between the inner electrode and the outer electrode, thus further reducing the crossing-profile of the device. In some embodiments, the inner electrode is formed by cutting the end of the insulated wire to expose an electrically conductive cross-section of the wire, and the end of the insulated wire is placed a controlled distance from the side edge of the conductive sheath as described above to form the electrode assembly. The assembling process is significantly easier than stacking the electrodes and aligning the opening of the conductive sheath with the opening of the insulating layer as required by previous designs, thus reducing manufacture cost and improving the usability and effectiveness of the shock wave device.

FIG. 1 depicts an exemplary shock wave angioplasty device 100 according to an embodiment of the invention. The shock wave device 100 includes an elongated tube 104 and an angioplasty balloon 102. The angioplasty balloon wraps circumferentially around a portion of the elongated tube 104 in a sealed configuration via, for example, a seal 122. The angioplasty balloon 102 forms an annular channel 124 around the elongated tube 104 through which a conductive fluid, such as saline, may be admitted into the balloon via fill ports 126. The balloon is filled with the fluid such that the balloon can be inflated and gently fixed to the walls of the artery in direct proximity with a calcified lesion. In some embodiments, the fluid may also contain an x-ray contrast to permit fluoroscopic viewing of the catheter during use.

The elongated tube 104 includes a number of longitudinal grooves or channels configured for retaining wires and/or inner electrodes. In the depicted example in FIG. 1 , the elongated tube 104 has four grooves along the length of the elongated tube. Insulated wires 130, 132, 134, and 136 are placed within the grooves of the elongated tube 104. Furthermore, a number of conductive sheaths 112, 114, and 116 are circumferentially mounted around the elongated tube 104. A variable high voltage pulse generator 150 is connected to the insulated wire 130 and the insulated wire 136. The insulated wires and the sheaths form three electrode assemblies that can be activated to generate shock waves at 6 locations (e.g., along the length of the vessel), as discussed in detail below. The elongated tube 104 also includes a lumen through which a guide wire 120 is inserted.

In operation, a physician uses the guidewire 120 to guide the elongated tube 104 into position. Once positioned, the variable high voltage pulse generator 150 is used to deliver a series of pulses to create a series of shock waves within the angioplasty balloon 102 and within the artery being treated. The magnitude of the shock waves can be controlled by controlling the magnitude of the pulsed voltage, the current, the duration, and the repetition rate. The physician may start with low energy shock waves and increase the energy as needed to crack the calcified plaques. Such shock waves will be conducted through the fluid, through the balloon, through the blood and vessel wall to the calcified lesion where the energy will break the hardened plaque.

FIG. 2A depicts a plurality of shock wave electrode assemblies that may be included in an exemplary shock wave angioplasty device such as the device depicted in FIG. 1 . As depicted, the shock wave angioplasty device 200 includes an elongated tube 204 having four longitudinal grooves 260, 262, 264, and 268. A number of insulated wires 230, 232, and 236 are disposed on the outer surface of the elongated tube 204 such that they extend along the length of the elongated tube. As depicted, the insulated wire 230 is disposed in the groove 264 and the insulated wire 232 is disposed in the groove 260. The insulated wire 236 has a first straight portion disposed in the groove 262, a second straight portion disposed in the groove 264, and a curved portion disposed between the grooves 262 and 264.

The shock wave angioplasty device 200 further includes a first conductive sheath 212 and a second conductive sheath 214 each circumferentially mounted around the elongated tube 204. As depicted in FIGS. 2A and 2B, the length of the first conductive sheath 212 overlaps with and covers a portion of the insulated wire 230 near its distal end, a portion of the insulated wire 232 near its proximal end, and a portion of the insulated wire 236. The length of the second conductive sheath 214 overlaps with and covers a portion of the insulated wire 232 near its distal end and a portion of the insulated wire 236 near its distal end.

The electrode assemblies of the shock wave angioplasty device 200 are described below with reference to FIGS. 2C and 2D. Turning to FIG. 2C, a portion of the insulating layer of the wire 230 is removed near the distal end of the wire 230 to expose an electrically conductive wire portion, forming the first inner electrode 230 a. In the depicted example, a hole in the insulating layer is cut on the curved outer surface along the length of the wire. The removed portion may be in any shape, such as a circle, a rectangle, a strip around the circumference of the wire, etc. The location, shape, and size of the removed portion may vary to control the location, direction, and/or magnitude of the shock wave. In some embodiments, an inner electrode may be formed by cutting the end of the wire to expose an electrically conductive cross-section of the wire. In some embodiments, flat wires rather than round wires are used to further reduce the crossing profile of the electrode assembly.

As shown in FIG. 2C, the first inner electrode 230 a is adjacent to, but not in contact with, a distal side edge 213 of the first conductive sheath 212. The first conductive sheath 212 functions as an outer electrode, and the first inner electrode 230 a is placed a controlled distance apart from the distal side edge 213 of the first conductive sheath to allow for a reproducible arc for a given voltage and current. The electrical arcs are then used to generate shock waves in the conductive fluid. In operation, a first shock wave is created across the first inner electrode 230 a and the distal side edge 213 of the first conductive sheath 212, the details of which are provided below with reference to FIG. 2E.

In a similar manner, a portion of the insulated wire 232 is removed to form a second inner electrode 232 a. Specifically, a portion of the insulating layer of the wire 232 is removed near the proximal end of the wire 232 to expose an electrically conductive wire portion along the length of the wire, forming the second inner electrode 232 a. As shown, the second inner electrode 232 a is adjacent to, but not in contact with, a proximal side edge 211 of the first conductive sheath 212. Further, the first inner electrode 230 a and the second inner electrode 232 a are positioned circumferentially 180 degrees from each other. In operation, the first conductive sheath 212 acts as an outer electrode and a second shock wave is created across the second inner electrode 232 a and the proximal side edge 211 of the first conductive sheath 212, the details of which are provided below with reference to FIG. 2E.

Turning to FIG. 2D, a third inner electrode 232 b is formed on the insulated wire 232 and a fourth inner electrode 236 a is formed on the insulated wire 236 in a similar manner as described above with reference to FIG. 2C. As depicted, the third inner electrode 232 b is formed near the distal end of the insulated wire 232 and is adjacent to, but not in contact with, a distal side edge 215 of the second conductive sheath 214. The fourth inner electrode 236 a is formed near the distal end of the insulated wire 236 and is adjacent to, but not in contact with, the same distal side edge 215 of the second conductive sheath 214. In operation, the second conductive sheath 214 acts as an outer electrode, a third shock wave is created across the third electrode 232 b and the distal side edge 215 and a fourth shock wave is created across the fourth electrode 236 a and the distal side edge 215, the details of which are provided below with reference to FIG. 2E.

In the depicted example in FIGS. 2C and 2D, the first conductive sheath 212 includes a first arcuate cut-out on the distal side edge 213, and the first inner electrode 230 a is positioned adjacent to the first arcuate cut-out such that the first shock wave is created across the first arcuate cut-out and the first inner electrode. Further, the first conductive sheath 212 includes a second arcuate cut-out on the proximal side edge 211 positioned circumferentially 180 degrees from the first cut-out, and the second inner electrode 232 a is positioned adjacent to the second arcuate cut-out such that the second shock wave is created across the second arcuate cut-out and the second inner electrode. The cut-outs on the conductive sheath allow the inner electrodes to be placed closer to the sheath without coming into direct contact with the sheath, and also allows for better control of the locations of the shock waves and more predictable and even wear on the conductive sheath. It should be appreciated by one of ordinary skill in the art that a shock wave can be generated between an inner electrode and a straight side edge of the conductive sheath that does not include any cut-outs.

FIG. 2E schematically depicts an electrical diagram of the configuration of FIGS. 2A-D, in accordance with some embodiments. When a high voltage is applied (e.g., using the high voltage pulse generator 150 of FIG. 1 ) across the proximal end of the insulated wire 230 and the proximal end of the insulated wire 236, a current may flow as indicated by the arrows, with the insulated wire 236 as the common ground wire (i.e., connecting to a ground or negative channel). As shown, the current flows from the proximal end of the insulated wire 230 toward to the distal end of the insulated wire 230 and, via the insulation removed spot that is electrically conductive (i.e., the first inner electrode 230 a), to the distal side edge 213 of the first conductive sheath 212 (i.e., the first outer electrode). The duration and the magnitude of the voltage pulse are set to be sufficient to generate a gas bubble at the surface of the first inner electrode 230 a causing a plasma arc of electric current to traverse the bubble and create a rapidly expanding and collapsing bubble, which creates the mechanical shock wave in the balloon. The size of the bubble and the rate of expansion and collapse of the bubble (and therefore the magnitude, duration, and distribution of the mechanical force) may vary based on the magnitude and duration of the voltage pulse, as well as the distance between the inner and outer electrodes, the surface area of the electrodes, and/or the shape of the outer electrode (e.g., whether there is an arcuate cut-out on the side edge).

The current may further traverse from the proximal side edge 211 of the first conductive sheath 212 (i.e., the first outer electrode) to the insulated wire 232, via the insulation removed spot near the proximal end of the insulated wire 232 (i.e., the second inner electrode 232 a). The voltage pulse may create a potential difference between the first outer electrode and the second inner electrode high enough to form a plasma arc between them, generating a bubble that gives rise to a second shock wave. In the depicted example, the first inner electrode 230 a and the second inner electrode 232 a are located circumferentially opposite to each other (e.g., 180 degrees apart around the circumference of the elongated tube), and thus the first shock wave and the second shock wave may propagate in opposite directions, extending outward from the side of the elongated tube.

The current may further traverse from the proximal end of the insulated wire 232 toward to the distal end of the wire and, via the insulation removed spot that is electrically conductive near the distal end of the wire (i.e., the third inner electrode 232 b), to the distal side edge 215 of the second conductive sheath 214 (i.e., the second outer electrode). The high voltage pulse generator may apply a voltage pulse such that the potential difference between the third inner electrode 232 b and the second outer electrode is high enough to form a plasma arc between them, generating a bubble that gives rise to a third shock wave.

The current may further traverse from the distal side edge 215 of the second conductive sheath 214 to the insulated wire 236, via the insulation removed spot on the insulated wire 236 (i.e., the fourth inner electrode 236 a). The voltage pulse may create a potential difference between the second outer electrode and the fourth inner electrode high enough to form a plasma arc between them, generating a bubble that gives rise to a fourth shock wave. The current then returns to the voltage source generator via the insulated wire 236 to a voltage output port (not depicted), which may be a negative channel or a ground channel. Optionally, a connector (not depicted) may be provided between the insulated wires 230 and 236 and the voltage pulse generator so that the wires may be easily connected to the output ports of the high voltage generator. It should be appreciated that the configuration depicted in FIG. 2E can operate as described above regardless of whether the side edges of the conductive sheaths are straight or have arcuate cut-outs.

In the embodiments depicted in FIGS. 2A-E, each electrode assembly includes a pair of inner electrodes configured to generate shock waves at two locations. For example, the electrode assembly consisting of conductive sheath 212 and inner electrodes 230 a and 232 a is configured to generate two shock waves via the two inner electrodes positioned circumferentially 180 degrees from each other. Further, the device 200 includes multiple electrode assemblies along the length of the elongated tube. Since the magnitude, duration, and distribution of the mechanical force impinging on a portion of tissue depends at least in part on the location and distance between the shock wave source and the tissue portion, a shock wave device having multiple shock wave electrodes at different locations (circumferentially and longitudinally) may help to provide consistent or uniform mechanical force to a region of tissue. The plurality of electrodes may be distributed across the device to minimize the distance between the shock wave source(s) and the tissue location being treated. In some embodiments, the elongated tube may be sized and shaped to distribute shock wave forces to a non-linear anatomical region (e.g., valve and/or valve leaflets). It should also be appreciated that the voltage polarity can be reversed and current flow in the opposite direction.

It should be appreciated that, in some embodiments, an electrode assembly may include a single inner electrode that is configured to generate shock wave at a single location. For example, with reference to FIG. 2E, insulated wires 232 and 236 may be removed, and a common ground wire may connect the conductive sheath 322 (e.g., the distal edge 213 of the conductive sheath) directly to the ground or negative channel of a voltage source. This way, as a current flows from the insulated wire 230 to the conductive sheath 212 to the common ground wire, a shock wave is generated at a single location (i.e., across the inner electrode 230 a and the distal side edge 213 of the conductive sheath).

FIGS. 3A-3B depict another set of shock wave electrode assemblies that may be included in an exemplary shock wave angioplasty device such as the device depicted in FIG. 1 . As discussed above, FIGS. 2A-2E relate to an exemplary configuration of electrode assemblies that may be activated to generate shock waves at 4 locations. In contrast, FIGS. 3A-3B relate to an exemplary configuration of electrode assemblies that may be activated to generate shock waves at 6 locations, as discussed below.

As depicted in FIG. 3A, an exemplary shock wave angioplasty device 300 comprises an elongated tube 304 having four longitudinal grooves on the outer surface. A first conductive sheath 312, a second conductive sheath 314, and a third conductive sheath 316 are each circumferentially mounted around the elongated tube 304. A number of insulated wires 330, 332, 334, and 336 are disposed on the outer surface of the elongated tube 304 such that they extend along the outer surface of the elongated tube. In particular, the insulated wire 330 is disposed within a single groove in its entirety, while the insulated wires 332, 334, and 336 are each disposed within multiple grooves. For example, as shown in FIG. 3A, the insulated wire 334 includes a first straight portion disposed within one groove, a second straight portion disposed within the adjacent groove, and a curved portion disclosed between the two grooves.

The conductive sheaths 312, 314, and 316 and the insulated wires 330, 332, 334, and 336 form three electrode assemblies that can be activated to generate shock waves at 6 locations. Turning to FIG. 3B, a portion of the insulated wire 330 is removed to form a first inner electrode 330 a. As discussed above, a portion of the insulating layer of the wire 330 may be removed by cutting a hole in the insulating layer near the distal end of the wire 330 to expose an electrically conductive wire portion along the length of the wire, forming the first inner electrode 330 a. Alternatively, the inner electrode 330 a may be formed by cutting the distal end of the wire to expose an electrically conductive cross-section of the wire. As shown, the first inner electrode 330 a is adjacent to, but not in contact with, the distal side edge of the first conductive sheath 312. In operation, the first conductive sheath 312 acts as an outer electrode and a first shock wave is created across the first inner electrode 330 a and the distal side edge of the first conductive sheath 312.

Furthermore, a second inner electrode 332 a and a third inner electrode 332 b are formed by removing a portion of the insulated wire 332 (e.g., cutting a hole in the insulating layer, cutting the end of the wire to expose an electrically conductive cross section) near the proximal end and removing a portion of the insulated wire 332 near the distal end, respectively. A fourth inner electrode 334 a and a fifth inner electrode 334 b are formed by removing a portion of the insulated wire 334 near the proximal end and removing a portion of the insulated wire 334 near the distal end, respectively. A sixth inner electrode 336 a is formed by removing a portion of the insulated wire 336 near the distal end.

In operation, the proximal end of the insulated wire 330 and the proximal end of the insulated wire 336 are connected to the output ports of a high voltage pulse generator (e.g., the high voltage pulse generator 150 in FIG. 1 ). A high voltage is applied across the insulated wire 330 and 336 such that a current flows as indicated by the arrows in FIG. 3B, with the insulated wire 336 as the common ground wire. Specifically, the current traverses from the insulated wire 330 to the distal side edge of the first conductive sheath 312, creating a first shock wave across the first inner electrode 330 a and the distal side edge. The current then traverses from the proximal side edge of the first conductive sheath 312 to the insulated wire 332, creating a second shock wave across the proximal side edge and the second inner electrode 332 a. The first inner electrode 330 a and the second inner electrode 332 a are positioned circumferentially 180 degrees from each other. As such, the first shock wave and the second shock wave may propagate in opposite directions, extending outward from the side of the elongated tube.

The current then traverses from insulated wire 332 to the distal side edge of the second conductive sheath 314, creating a third shock wave across the third inner electrode 332 b and the distal side edge. The current then traverses from the proximal side edge of the second conductive sheath 314 to the insulated wire 334, creating a fourth shock wave across the proximal side edge of the second conductive sheath 314 and the fourth inner electrode 334 a. The third inner electrode 332 b and the fourth inner electrode 334 a are positioned circumferentially 180 degrees from each other. Further, the first inner electrode 330 a and the third inner electrode 332 b are positioned circumferentially 90 degrees from each other. As depicted in FIG. 3B, the first inner electrode 330 a is positioned adjacent to an arcuate cut-out 350 on the distal side edge of the first conductive sheath 312, while the third inner electrode 332 b is positioned adjacent to an arcuate cut-out 351 on the distal side edge of the second conductive sheath. As depicted, the two cut-outs 350 and 351 are positioned circumferentially 90 degrees from each other.

The current then traverses from the insulated wire 334 to the distal side edge of the third conductive sheath 316, creating a fifth shock wave across the distal side edge of the third conductive sheath 316 and the fifth inner electrode 334 b. The current then traverses from the distal side edge of the third conductive sheath 316 to the insulated wire 336, creating a sixth shock wave across the distal side edge of the third conductive sheath 316 and the sixth inner electrode 336 a. The current then returns to the output port (not depicted), which may be a negative channel or a ground channel.

In the depicted example in FIG. 3B, the first shock wave and the second shock wave are generated on the distal side edge and the proximal side edge of the first conductive sheath 312, respectively, due to the diagonal placement of the inner electrodes 330 a and 332 a relative to the first conductive sheath 312. The diagonal placement of the inner electrodes allows the sonic output to be distributed more evenly longitudinally along the balloon while making the shock waves less annular. In contrast, the fifth shock wave and the sixth shock wave are both generated on the distal side edge of the third conductive sheath 316, due to the placement of the inner electrodes 334 b and 336 a relative to the third conductive sheath 316. These configurations maintain the continuity in case a wire breaks at the firing spot. One of ordinary skill in the art should recognize that the location of a shock wave can be configured in a flexible manner by arranging the corresponding wire and the corresponding conductive sheath (and the location of the corresponding cut-out on the sheath, if available) accordingly.

FIGS. 4A-D depict another set of shock wave electrode assemblies that may be included an exemplary shock wave angioplasty device such as the device depicted in FIG. 1 . As described above, the embodiments depicted in FIGS. 2A-2E and FIGS. 3A-B can each generate shock waves at multiple locations (4 and 6 respectively) via a single current. In contrast, the embodiment depicted in FIGS. 4A-D relate to an exemplary configuration of electrode assemblies that may be activated to generate multiple shock waves via multiple currents, as discussed below. Specifically, two separate currents are generated in order to create shock waves in eight locations.

As depicted in FIG. 4A and FIG. 4B, an exemplary shock wave angioplasty device 400 comprises an elongated tube 404 having four longitudinal grooves on the outer surface. A first conductive sheath 412, a second conductive sheath 414, a third conductive sheath 416, and a fourth conductive sheath 418 are each circumferentially mounted around the elongated tube 404. A number of insulated wires 430, 432, 434, 436, and 438 are disposed on the outer surface of the elongated tube 404 such that they extend along the outer surface of the elongated tube. In particular, some insulated wires (e.g., insulated wires 432 and 436) are each disposed within a single groove in its entirety, while some insulated wires (e.g., insulated wires 434 and 438) are each disposed within multiple grooves.

The conductive sheaths 412, 414, 416, and 418 and the insulated wires 430, 432, 434, 436, and 438 form four electrode assemblies that can be activated to generate shock waves at 8 locations. Turning to FIG. 4B, a portion of the insulated wire 430 is removed to form a first inner electrode 430 a. Furthermore, a second inner electrode 432 a and a third inner electrode 432 b are formed by removing a portion of the insulated wire 432 near the proximal end and removing a portion of the insulated wire 432 near the distal end, respectively. A fourth inner electrode 438 a is formed by removing a portion of the insulated wire 438. A fifth inner electrode 434 a is formed by removing a portion of the insulated wire 434 near the distal end. A sixth inner electrode 436 a and a seventh inner electrode 436 b are formed by removing a portion of the insulated wire 436 near the proximal end and removing a portion of the insulated wire 436 near the distal end, respectively. An eighth inner electrode 438 b is formed by removing a portion of the insulated wire 438 near the distal end.

Any of inner electrodes 430 a, 432 a, 432 b, 434 a, 434 b, 436 a, 436 b, and 438 b may be formed by removing a portion of the corresponding wire in any manner that can expose an electrically conductive portion of the wire, for example, by cutting a hole in the insulating layer or cutting the end of the wire to expose an electrically conductive cross section. Inner electrode 438 a may be formed by removing a portion of the insulated wire 438 (e.g., cutting a hole in the insulating layer) on the outer surface of the wire adjacent to a side edge of the second conductive sheath 414.

FIG. 4C schematically depicts an electrical diagram of the configuration of FIGS. 4A and 4B, in accordance with some embodiments. In operation, the proximal end of the insulated wire 430 and the proximal end of the insulated wire 438 are first connected to the output ports of a high voltage pulse generator (e.g., the high voltage pulse generator 150 in FIG. 1 ), with the insulated wire 438 as the common ground wire. A high voltage is applied across the insulated wire 430 and 438 such that a first current 4 a flows as indicated by the arrows in FIG. 4C. Specifically, the first current 4 a traverses from the insulated wire 430 to the distal side edge of the first conductive sheath 412, creating a first shock wave across the first inner electrode 430 a and the distal side edge of the first conductive sheath 412. The first current 4 a then traverses from the proximal side edge of the first conductive sheath 412 to the insulated wire 432, creating a second shock wave across the proximal side edge of the first conductive sheath 412 and the second inner electrode 432 a. The current then traverses from insulated wire 432 to the distal side edge of the second conductive sheath 414, creating a third shock wave across the third inner electrode 432 b and the distal side edge of the second conductive sheath 414. The current then traverses from the proximal side edge of the second conductive sheath 414 to the insulated wire 438, creating a fourth shock wave across the proximal side edge of the second conductive sheath 414 and the fourth inner electrode 438 a. The current then returns to the output port (not depicted), which may be a negative channel or a ground channel.

FIG. 4D schematically depicts another electrical diagram of the configuration of FIGS. 4A and 4B, in accordance with some embodiments. The proximal end of the insulated wire 434 and the proximal end of the insulated wire 438 can be connected to the output ports of the high voltage pulse generator (e.g., the high voltage pulse generator 150 in FIG. 1 ). The high voltage is applied across the insulated wire 434 and 438 such that a second current 4 b flows as indicated by the arrows in FIG. 4C. Specifically, the first current 4 b traverses from the insulated wire 434 to the distal side edge of the third conductive sheath 416, creating a fifth shock wave across the fifth inner electrode 434 a and the distal side edge of the third conductive sheath 416. The second current 4 b then traverses from the proximal side edge of the third conductive sheath 416 to the insulated wire 436, creating a sixth shock wave across the proximal side edge of the third conductive sheath 416 and the sixth inner electrode 436 a. The current then traverses from insulated wire 436 to the distal side edge of the fourth conductive sheath 418, creating a seventh shock wave across the seventh inner electrode 436 b and the distal side edge of the fourth conductive sheath 418. The current then traverses from the distal side edge of the fourth conductive sheath 418 to the insulated wire 438, creating a eighth shock wave across the distal side edge of the fourth conductive sheath 418 and the eighth inner electrode 438 b. The current then returns to the output port (not depicted), which may be a negative channel or a ground channel.

As such, in the embodiment shown in FIGS. 4A-D, two voltage channels are used to generate two separate current flows, which in turn generate shock waves at 8 different locations. In some embodiments, the high voltage pulse generator may drive the insulated wire 430 and 434 simultaneously. For example, the physician may simultaneously connect the insulated wire 430 to a first positive lead of the pulse generator, connect the insulated wire 434 to a second positive lead of the pulse generator, and connect the insulated wire 438 to a negative lead or the ground. In some embodiments, the high voltage pulse generator may apply voltage pulses sequentially (e.g., a voltage pulse is applied to the insulated wire 430 without applying a pulse to the insulated wire 434). In some embodiments, the voltage pulses applied to the insulated wire 434 may be delayed with respect to the voltage pulses applied to the insulated wire 430. In some embodiments, a multiplexor may be used with the high voltage pulse generator to control application of pulses. This may allow shock waves with different frequency, magnitude, and timing to be generated along the elongated tube. In the depicted embodiment in FIGS. 4A-D, the two voltage channels share the same common ground wire (i.e., insulated wire 438). One of ordinary skill in the art should understand that any number of voltage channels (e.g., 4) may be configured around a single elongated tube, and these voltage channels may rely on the same or different common ground wires.

In contrast with the embodiment depicted in FIGS. 3A-B, in which three electrode assemblies are connected in series, the embodiment depicted in FIGS. 4A-D is configured such that some of the electrode assemblies (e.g., any electrode assembly on the path of current 4 a vs. any electrode assembly on the path of current 4 b) operate on different voltage channels. The series configuration (e.g., as shown in FIGS. 3A-B) may allow for more shock waves to be simultaneously generated using fewer wires than if, for example, each electrode assembly is connected to a separate voltage channel. Reducing the number of wires along the length of the elongated tube may help to maintain the ability of the elongated tube to bend and flex (e.g., to navigate through tortuous vasculature) and fit into more treatment areas. On the other hand, the voltage applied to a series configuration needs to be greater and/or of longer duration than the voltage applied to electrode assemblies each connected to separate voltage channels in order to attain a shock wave of similar magnitude. As such, a shock wave as depicted in FIGS. 4A-D, in which some electrode assemblies are connected in series (e.g., conductive sheaths 412 and 414) while some electrode assemblies are controlled by different voltage channels (e.g., conductive sheaths 412 and 416), may provide the ability to apply a stronger shock wave when desired, but also have the ability to simultaneously apply many shock waves without substantially compromising the flexibility and turning capability of the device by minimizing the number of wires.

It should be appreciated that a shock wave device may include any number of conductive sheaths and thus, any number of electrode assemblies. FIG. 5 depicts another set of shock wave electrode assemblies that may be included an exemplary shock wave angioplasty device such as the device depicted in FIG. 1 . The embodiment depicted in FIG. 5 relates to an exemplary configuration of electrode assemblies that may be activated to generate 10 shock waves via a single voltage channel. As depicted in FIG. 5 , the shock wave device includes five conductive sheaths and six wires. In operation, in response to a voltage being applied, a current flows through the six wires as indicated by the arrows, generating ten shockwaves (SW1-SW10) as illustrated.

With reference to FIGS. 1-5 , each of the above-described conductive sheaths may be constructed in any electrically conductive material and may take any shape. As discussed above, any number of cut-outs may be created on a conductive sheath to improve the performance of the electrode assembly. In some embodiments, the number and locations of the cut-outs on the conductive sheath may vary based on the intended configuration of the electrode assembly. For example, a conductive sheath depicted in FIG. 6A includes two cut-outs positioned circumferentially 180 degrees from each other on the same side edge. This embodiment can be used to construct an electrode assembly that generates two shock waves that are circumferentially 180 degrees from each other on the same side edge of the conductive sheath, such as the conductive sheaths 214, 316, and 418. As another example, a conductive sheath depicted in FIG. 6B includes two cut-outs positioned circumferentially 180 degrees from each other on opposite side edges of the conductive sheath. This embodiment can be used to construct an electrode assembly that generates two shock waves that are circumferentially 180 degrees from each other on the opposite side edges of the conductive sheath, such as the conductive sheaths 212, 312, and 412. In some embodiments, a sheath having a larger number of cut-outs may be created to improve the versatility of the sheath and reduce manufacture cost. For example, a sheath having four cut-outs that are positioned circumferentially 90 degrees apart on each side edge of the conductive sheath can be used in place of any of the above-described conductive sheaths.

Further, a conductive sheath may be created from multiple sub-components. In some embodiments, the conductive sheath includes multiple sub-components having notches and/or recesses that may be interlocked to form the conductive sheath, such as the conductive sheath having two halves dovetailed together as depicted in FIGS. 6C-D. In some embodiments, the conductive sheath includes multiple sub-components that can be pieced together by way of any suitable method, such as soldering, crimping, welding, conductive adhesives, pressure fit, interference fit, to form the conductive sheath. The multiple sub-components may allow for easy configuration of the electrode assembly because, for example, a technician may first position the insulated wires into the grooves of the elongated tube and then crimp the two halves of the conductive sheath over the elongated tube to amount the conductive sheath.

In some embodiments, the conductive sheath is created as a single piece to minimize potential damages (e.g., scratching) to the insulated wires during assembly. In some embodiments, during assembly, the elongated tube is stretched to reduce its circumference to allow a conductive sheath to be slid onto the elongated tube. The insulated wires are then positioned under the conductive sheath by, for example, sliding the wires into the grooves of the elongated tube. The elongated tube is then relaxed such that its circumference is increased and the conductive sheath is securely mounted over the elongated tube.

FIGS. 7A-C depict an exemplary construction of an electrode assembly, in accordance with some embodiments. As depicted in FIG. 7A, an insulated wire 630 is positioned on the outer surface of an elongated tube 604, and a conductive sheath 612 is circumferentially mounted on the elongated tube 604 and covers a longitudinal portion of the insulated wire. Further, a portion of the insulating layer of the wire 630 (along with any adhesives applied) is removed from the insulated wire 630 to form an inner electrode 630 a. The inner electrode 630 a (e.g., the inside of the wire) may be made of materials that can withstand high voltage levels and intense mechanical forces that are generated during use, for example, stainless steel, tungsten, nickel, iron, steel, and the like.

In some embodiments, one or more pieces of tubing (e.g., heat shrink tubing) may be provided over the elongated tube 604 to help retain the wire 630 within the groove while still allowing the wires to slide and move within the groove(s) to accommodate bending of the elongated tube. For example, one or more bands of shrink tubing may wrap circumferentially around one or more portions of the insulated wire 630, including one end 613 of the wire 630. In the depicted example in FIG. 7B, two bands of heat shrink tubing 640 a and 640 b are used to secure the wire 630, with the bottom band 640 b covering the end 613 of the wire 630 and a portion of the elongated tube 604. In some embodiments, the bottom band 640 b may abut up to the bottom side edge of the conductive sheath 612 while not covering insulation removal spot 630 a.

The generation of plasma arcs may cause the cut-out of the sheath 612 to erode and take on a slot-like shape over time. If the end of the wire 631 is cut to form an inner electrode and the end of the wire is not secured to the elongated tube, the wire may curl up (e.g., like a candle wick) over time, compromising the effectiveness and longevity of the electrode assembly. By forming the inner electrode using an insulation removal spot 630 a and securing the end of the wire to the elongated tube using a shrink tube, the life of the electrode assembly is extended.

Alternatively or additionally, adhesives (e.g., dots of conductive epoxy) may be applied along a portion of the wire and/or near the conductive sheath to partially secure or retain the wire within the groove(s) while still maintaining the ability of the wire to partially move and shift as the elongated tube bends or curves. In the depicted example in FIG. 7C, adhesives are applied along the side edges of the conductive sheath 612 and the side edges of the tubing.

In each of the embodiments depicted in FIGS. 2A, 3A, and 4A, the elongated tube includes four longitudinal grooves, spaced circumferentially 90 degrees apart, for accommodating insulated wires. It should be appreciated that the elongated tube can include any number of grooves (e.g., 6, 8). For example, for a relatively long balloon housing a large number of conductive sheaths along the length of the balloon, a larger number of wires may be required. Such system would be easier to construct, configure, and/or operate using an elongated tube having a larger number of grooves.

Any of the shock wave assemblies described herein may be used in an angioplasty procedure for breaking up calcified plaques accumulated along the walls of a vessel. One variation of a method may comprise advancing a guide wire from an entry site on a patient (e.g., an artery in the groin area of the leg) to the target region of a vessel (e.g., a region having calcified plaques that need to be broken up). A shock wave device comprising an elongated tube with a guide wire lumen, one or more electrode assemblies located along the elongated tube, and a balloon may be advanced over the guide wire to the target region of the vessel. The shock wave electrode assemblies may be any of the electrode assemblies described herein. The balloon may be collapsed over the elongated member while the device is advanced through the vasculature. The location of the shock wave device may be determined by x-ray imaging and/or fluoroscopy. When the shock wave device reaches the target region, the balloon may be inflated by a conductive fluid (e.g., saline and/or saline mixed with an image contrast agent). The one or more electrode assemblies may then be activated to generate shock waves to break up the calcified plaques. The progress of the plaque break-up may be monitored by x-ray and/or fluoroscopy. The shock wave device may be moved along the length of the vessel if the calcified region is longer than the length of the catheter with the electrode assemblies, and/or if the calcified region is too far away from the electrode assemblies to receive the full force of the generated shock waves. For example, the shock wave device may be stepped along the length of a calcified vessel region to sequentially break up the plaque. The electrode assemblies of the shock wave device may be connected in series and/or may be connected such that some electrode assemblies are connected to separate high voltage channels, which may be activated simultaneously and/or sequentially, as described above. Once the calcified region has been sufficiently treated, the balloon may be inflated further or deflated, and the shock wave device and guide wire may be withdrawn from the patient.

It will be understood that the foregoing is only illustrative of the principles of the invention, and that various modifications, alterations and combinations can be made by those skilled in the art without departing from the scope and spirit of the invention. Any of the variations of the various shock wave devices disclosed herein can include features described by any other shock wave devices or combination of shock wave devices herein. Furthermore, any of the methods can be used with any of the shock wave devices disclosed. Accordingly, it is not intended that the invention be limited, except as by the appended claims. For all of the variations described above, the steps of the methods need not be performed sequentially 

What is claimed is:
 1. (canceled)
 2. A method for treating calcified lesions in vessels of a patient comprising: advancing a device for generating shock waves into a vessel of the patient, the device comprising: an elongated tube; a member sealed to a distal end of the elongated tube that is fillable with a conductive fluid, and a shock wave generation station within the member, the shock wave generation station comprising: a conductive sheath circumferentially mounted around the elongated tube, and at least two wires passing at least partially through the conductive sheath between an outer surface of the elongated tube and an inner surface of the conductive sheath, each wire having an exposed portion defining an electrode that is spaced apart from the conductive sheath by a gap; applying a high voltage across the wires to cause current to flow between each electrode and the conductive sheath to create a separate shock wave at each gap; and removing the device from the vessel of the patient.
 3. The method of claim 2, comprising filling the member with conductive fluid before applying the high voltage and draining the member before removing the device from the vessel of the patient.
 4. The method of claim 2, wherein the electrodes defined by the at least two wires are located adjacent the same end of the conductive sheath.
 5. The method of claim 4, wherein the electrodes defined by the at least two wires are circumferentially offset from one another.
 6. The method of claim 2, wherein the electrodes defined by the at least two wires are located adjacent different ends of the conductive sheath.
 7. The method of claim 2, wherein the elongated tube includes one or more grooves for receiving the at least two wires.
 8. The method of claim 2, wherein each wire of the at least two wires comprises an insulating layer surrounding at least a portion a length of the wire, the exposed portion lacking the insulating layer.
 9. The method of claim 2, wherein each wire of the at least two wires comprises an insulated layer having a strip of the insulating layer removed to form the exposed portion.
 10. The method of claim 2, wherein each electrode is adjacent a straight edge of the conductive sheath.
 11. The method of claim 2, each electrode is adjacent an arcuate cut-out of the conductive sheath.
 12. The method of claim 11, wherein the conductive sheath comprises a first arcuate cut-out on a first end of the sheath adjacent to a first electrode and a second arcuate cut-out on a second end of the sheath adjacent to a second electrode, with the first arcuate cut-out and second arcuate cut-out circumferentially offset 180 degrees from one another.
 13. The method of claim 2, wherein the member is a balloon.
 14. The method of claim 2, comprising multiple wave generation stations that are laterally spaced along a length of the tube within the member.
 15. The method of claim 14, wherein a first wire of the at least two wires extends through a conductive sheath of each of the multiple shock wave generation stations, the first wire connectable to a first terminal of a voltage supply.
 16. The method of claim 15, wherein a second wire of the at least two wires extends through the conductive sheath of each of the multiple shock wave generation stations, and wherein a third wire extends at one end through one conductive sheath, with an opposite end of the third wire connectable to a second terminal of the voltage supply.
 17. The method of claim 2, wherein the device at least four shock wave generation stations laterally spaced along the length of the tube within the member, and the method comprises: selectively connecting a power supply to one of a first channel that comprises at least two shock wave generation stations of the at least four shock wave generation stations and a second channel that comprises at least two other shock wave generation stations of the at least four shock wave generation stations; applying the high voltage to the first channel to generate shock waves at each of the at least two shock wave generation stations of the first channel; and subsequently applying the high voltage to the second channel to generate shock waves at each of the at least two other shock wave generation stations of the second channel.
 18. The method of claim 17, wherein both the first channel and second channel share a common wire.
 19. The method of claim 18, wherein the common wire is connected to a ground terminal of the power supply. 